Integrated artificial neuron device

ABSTRACT

An artificial-neuron device includes an integration-generation circuit coupled between an input at which an input signal is received and an output at which an output signal is delivered, and a refractory circuit inhibiting the integrator circuit after the delivery of the output signal. The refractory circuit is formed by a first MOS transistor having a first conduction-terminal coupled to a supply node, a second conduction-terminal coupled to a common node, and a control-terminal coupled to the output, and a second MOS transistor having a first conduction-terminal coupled to the input, a second conduction-terminal coupled to a reference node at which a reference voltage is received, and a control-terminal coupled to the common node. A resistive-capacitive circuit is coupled between the supply node and the reference node and having a tap coupled to the common node, with the inhibition duration being dependent upon a time constant of the resistive-capacitive circuit.

PRIORITY CLAIM

This application is a continuation of U.S. patent application Ser. No. 15/694,510, filed Sep. 1, 2017, which claims the priority benefit of French Application for Patent No. 1752383, filed on Mar. 23, 2017, the disclosures of which are hereby incorporated by reference in their entireties to the maximum extent allowable by law.

TECHNICAL FIELD

Embodiments relate to artificial intelligence and, in particular, to the creation of networks of neurons in the context of what is known to those skilled in the art as ‘deep learning’. More particularly, embodiments relate to integrated electronic circuits that simulate the behavior of neurons.

BACKGROUND

A biological neuron comprises a plurality of parts, including: one or more dendrites that deliver(s) an electrical input signal; the body of the neuron or soma which accumulates the input signal in the form of a potential difference between the interior and the exterior of its membrane; and an axon configured to deliver an output signal or action potential when the voltage between the exterior and the interior of the membrane reaches a certain threshold. In a biological neuron, electrical leakages occur through the membrane if electrical equilibrium is not achieved between the interior and the exterior of the membrane.

An artificial neuron should mimic the biological neuron and thus be capable of receiving an input signal, integrating the input signal and, when the integrated signal reaches a threshold, emitting an output signal in the form of one or more voltage spikes.

In the field of networks of artificial neurons, the acronym LIF (‘Leaky Integrate-and-Fire’) denotes a simple behavioral model of the artificial neuron, in which the artificial neuron receives and accumulates an input signal until a threshold value is exceeded, beyond which threshold value the neuron emits an output signal.

This model takes into account, in particular, the electrical leakages of the neuron through the membrane of the neuron.

The neuron may either receive a series of successive current spikes until an output current spike is generated, or receive a continuous signal at the input and generate a train of current spikes at the output.

Solutions exist for the creation of artificial neurons in accordance with the LIF model including, for example, the use of several tens of transistors and at least one capacitor of large size, typically one hundred square micrometers.

Because of the large size of the capacitor, the reaction time of this type of circuit is of the order of one millisecond.

Moreover, applications in the field of artificial intelligence, such as, for example but without limitation, the simulation of brain activity, require the creation of networks including a very large number of artificial neurons, typically of the order of one billion. It would thus be very advantageous to use integrated circuits of reduced size.

Solutions exist that use neurons of more reduced sizes and that make it possible to achieve higher operating speeds, but these solutions require the implementation of specific manufacturing methods.

SUMMARY

Disclosed herein is an integrated artificial neuron device, including: an integration-generation circuit coupled between an input node at which at least one input signal is received and an output node at which the integration-generation circuit delivers at least one output signal; and a refractory circuit configured to inhibit the integrator circuit for an inhibition duration after the delivery of the at least one output signal.

The refractory circuit includes: a first MOS transistor having a first conduction terminal coupled to a supply node, a second conduction terminal coupled to a common node, and a control terminal coupled to the output node; a second MOS transistor having a first conduction terminal coupled to the input node, a second conduction terminal coupled to a reference node at which a reference voltage is received, and a control terminal coupled to the common node; and a resistive-capacitive circuit coupled between the supply node and the reference node and having a tap coupled to the common node, wherein the inhibition duration is dependent upon a time constant of the resistive-capacitive circuit.

The resistive-capacitive circuit may include a capacitor coupled between the supply node and the common node, and a resistor coupled between the common node and the reference node.

The resistive-capacitive circuit may include a capacitor directly electrically connected between the supply node and the common node, and a resistor directly electrically connected between the common node and the reference node.

The capacitor may be formed by a MOS transistor configured for use as a capacitor. The MOS transistor of the capacitor may have a surface area of one square micrometer.

The resistor may be formed by a MOS transistor configured for use as a resistor. The resistor may have a resistance of one giga-ohm.

The first MOS transistor may be a first n-channel transistor having a drain coupled to the supply node, a source coupled to the common node, and a gate coupled to the output node, and the second MOS transistor may be a second n-channel transistor having a drain coupled to the input node, a source coupled to the reference node, and a gate coupled to the common node.

The first MOS transistor may be a first n-channel transistor having a drain directly electrically connected to the supply node, a source directly electrically connected to the common node, and a gate directly electrically connected to the output node, and the second MOS transistor may be a second n-channel transistor having a drain directly electrically connected to the input node, a source directly electrically connected to the reference node, and a gate directly electrically connected to the common node.

Also disclosed herein is a refractory circuit configured to inhibit operation of an integrator circuit after delivery of an output signal. The refractory circuit includes: a first MOS transistor having a first conduction terminal coupled to a supply node, a second conduction terminal coupled to a common node, and a control terminal coupled to an output node at which the output signal is delivered; a second MOS transistor having a first conduction terminal coupled to an input node, a second conduction terminal coupled to a reference node at which a reference voltage is received, and a control terminal coupled to the common node; and a resistive-capacitive circuit coupled between the supply node and the reference node and having a tap coupled to the common node, wherein a duration of inhabitation of the integrated circuit by the refractory circuit is dependent upon a time constant of the resistive-capacitive circuit.

The resistive-capacitive circuit may include a capacitor coupled between the supply node and the common node, and a resistor coupled between the common node and the reference node.

The resistive-capacitive circuit may include a capacitor directly electrically connected between the supply node and the common node, and a resistor directly electrically connected between the common node and the reference node.

The capacitor may be formed from a MOS transistor configured for use as a capacitor. The MOS transistor of the capacitor may have a surface area of one square micrometer.

The resistor may be a MOS transistor configured for use as a resistor. The resistor may have a resistance of one giga-ohm.

The first MOS transistor may be a first n-channel transistor having a drain coupled to the supply node, a source coupled to the common node, and a gate coupled to the output node, and the second MOS transistor may be a second n-channel transistor having a drain coupled to the input node, a source coupled to the reference node, and a gate coupled to the common node.

The first MOS transistor may be a first n-channel transistor having a drain directly electrically connected to the supply node, a source directly electrically connected to the common node, and a gate directly electrically connected to the output node, and the second MOS transistor may be a second n-channel transistor having a drain directly electrically connected to the input node, a source directly electrically connected to the reference node, and a gate directly electrically connected to the common node.

BRIEF DESCRIPTION OF THE DRAWINGS

Other advantages and features of the invention will become apparent upon examining the detailed description of completely non-limiting embodiments of the invention and the appended drawings, in which:

FIG. 1 schematically illustrates from an electrical point of view an integrated artificial neuron device;

FIGS. 2 and 3 show the progression of an input signal Se, an integrated signal and an output signal during operation of the artificial neuron device of FIG. 1;

FIG. 4 schematically illustrates from an electrical point of view an integrated artificial neuron device;

FIG. 5 schematically illustrates from an electrical point of view an integrated artificial neuron device with a refractory circuit; and

FIG. 6 illustrates a network of artificial neurons.

DETAILED DESCRIPTION

FIG. 1 illustrates, schematically and from an electrical point of view, an integrated artificial neuron device DIS, produced in and on a semiconductor substrate that may be either a bulk substrate or a substrate of silicon-on-insulator type and configured in particular to implement the LIF neuron model.

The operation of the neuron device DIS in this case is therefore analogous to that of a biological neuron.

The device DIS includes an input node BE configured to receive an input signal Se, an output node BS configured to deliver an output signal Ss, and a reference node BR configured to receive a reference voltage, in this case ground for example.

The input signal may come from a single source or else be the combination of a plurality of different signals originating from different sources at the node BE.

The device also includes an integrator circuit 1, configured to receive and integrate the input signal Se and to deliver an integrated input signal Si, and a generator circuit 2, configured to deliver the output signal Ss when the integrated signal reaches a threshold (or ‘triggering threshold’).

The integrator circuit 1 in this case includes a main capacitor C1 coupled between the input node BE and the reference node BR.

The main capacitor in this case is an MOS capacitor having a surface area of one square micrometer.

The generator circuit 2 includes a main MOS transistor TR1 having a first electrode, in this case its drain d1, that is coupled to the input node BE, a second electrode, in this case its source s1, that is coupled to the reference node BR, and a gate g1 that is coupled to the output node BS.

The substrate sb1 of the main MOS transistor is coupled electrically to the gate g1 (in an embodiment, using a direct electrical connection).

The main MOS transistor TR1 includes a parasitic bipolar transistor where the base is the substrate of the MOS transistor, the collector is the drain d1 and the emitter is the source s1.

In this case, the main MOS transistor has a gate width of one micrometer and a gate length (distance between drain and source) of one hundred nanometers.

A control circuit CC is coupled between the substrate sb1 and the reference node BR and is configured to adjust a value of the triggering threshold of the generator circuit 2.

In this case, the control circuit includes a control resistor Rc having a resistance value of one gigaohm in this example.

Thus, in the presence of an input signal Se on the input node, the main capacitor C1 charges, and the value of the voltage across its nodes (the integrated signal) increases.

When the integrated signal Si, that is to say the voltage across the nodes of the capacitor C1 and of the first transistor TR1, reaches said triggering threshold, then the integrated signal Si is transmitted by means of the drain-substrate capacitance of the first transistor TR1 and the leakage currents of the drain-substrate junction on the substrate sb1 of the first transistor TR1, and by the drain-gate capacitance on the gate g1 of the first transistor TR1. The presence of the drain-substrate capacitance of the transistor TR1, which is very large with respect to the drain-gate capacitance of the transistor TR1, as well as the connection between the substrate and the gate of the transistor TR1, makes it possible to obtain operation of the MOS transistor in subthreshold mode, combined with intrinsic operation of the bipolar transistor.

Furthermore, these combined effects amplify one another mutually. Specifically, since the drain-substrate capacitance is very large with respect to the drain-gate capacitance, the pulse transmitted on the gate is weaker than that transmitted on the substrate. The connection between the gate g1 and the substrate sb1 enables the gate to bias to a greater extent (by way of the drain-gate capacitance but also by way of the bias of the substrate sb1) and, as a result, to amplify these combined effects, since the closer the gate voltage gets to the threshold voltage of the MOS transistor, the more the current gain of the parasitic bipolar transistor increases.

Moreover, the higher the product of the resistance of the control resistor Rc and the capacitance of the drain-substrate capacitance, the lower the value of the triggering threshold.

This type of integrator circuit is particularly advantageous as it makes it possible to obtain a low triggering threshold, for example of the order of one volt.

FIGS. 2 and 3 show the progression of the input signal Se, the integrated signal Si and the output signal Ss during operation of the artificial neuron device DIS.

In a first example illustrated by FIG. 2, the input node BE in this case receives a series of current spikes, having a constant or non-constant amplitude, in a regular or irregular manner, and that form the input signal Se.

The integrated signal Si, which corresponds to the voltage across the nodes of the capacitor, increases gradually and incrementally at each current spike.

When the integrated signal Si reaches the triggering threshold of the integrator circuit 2, 0.6 volts in this case, the main MOS transistor TR1 triggers, the capacitor C1 discharges through the MOS transistor TR1 and the gate is biased for a very brief duration. The bias spike of the gate in this case forms the output signal Ss.

Between each current spike of the input signal Se, the value of the voltage across the nodes of the capacitor drops slightly. This is due in particular to the leakage current of the main transistor TR1, which therefore simulates the electrical leakages through the membrane of the biological neuron.

In this first example, the input signal has a frequency of 1 megahertz and an amplitude of one hundred nanoamperes, with spikes of a duration of 20 nanoseconds, and the output signal has spikes of 753 nanoseconds at a frequency of 39 kilohertz.

In a second example illustrated by FIG. 3, the input node BE receives a direct current having a value of ten nanoamperes.

The integrated signal Si increases continuously until reaching the triggering threshold of the integrator circuit 2, 0.9 volts in this case. The main MOS transistor TR1 then triggers, and the capacitor C1 discharges through the MOS transistor TR1 and the gate is biased for a very brief duration.

In this second example, the duration to reach the threshold is much shorter than in the first example, and the frequency of the output signal is 1.11 megahertz.

The use of components of reduced size thus readily permits the use of high frequencies and a low electrical consumption.

The frequency and the amplitude of the output signal depend on several parameters, in particular on the doping and on the surface area of the main capacitor C1, which is an MOS capacitor, on the doping and on the dimensions of the main transistor, and on the value of the control resistor Rc.

A person skilled in the art will know to adjust these values depending on the envisaged applications.

According to one embodiment illustrated in FIG. 4, it is also possible that the control circuit CC includes a control transistor Tc having a first electrode that is coupled to the substrate of the first MOS transistor, a second electrode that is coupled to the reference node, and a gate that is configured to receive a control signal.

Depending on the value of the control signal, the resistance of the control transistor Tc in the ON state varies, thus adjusting the value of the triggering threshold of the main transistor TR1 and therefore of the generator circuit 2.

The control signal may, for example, be delivered by an adjunct module of the neuron device DIS, for example depending on the characteristics of the input signal, this in order to get still closer to the adaptable nature of biological neurons.

According to one embodiment illustrated in FIG. 5, the neuron device DIS includes a refractory circuit 3 that is configured to inhibit the integrator circuit 1 for an inhibition period. A supply node BV is configured to receive a supply voltage Vdd, for example a voltage of one volt in this case.

Specifically, it has been observed that biological neurons are inhibited for a period following the delivery of an action potential by the axon of the neuron.

The aim of this refractory circuit 3 is therefore to bring the operation of the neuron device DIS even closer still to the operation of a biological neuron.

The refractory circuit 3 includes a first secondary transistor Ts1 having a first electrode, in this case the drain Ds1, that is coupled to the input node, and a second electrode, in this case the source Ss1, that is coupled to the reference node.

The gate Gs1 of the first secondary transistor Ts1 is coupled to a common node N. A second secondary transistor Ts2 has a gate coupled to the output node BS, a first electrode, in this case the drain Ds2, that is coupled to the supply node BV, and a second electrode, in this case the source Ss2, that is coupled to the common node N.

A secondary capacitor Cs is coupled between the supply node BV and the common node N. The secondary capacitor Cs is in this case an MOS capacitor having, for example, a surface area of one square micrometer.

A secondary resistor Rs, for example in this case a resistor of one gigaohm that can be created in practice by an MOS transistor in the ON state, is coupled between the common node N and the reference node BR.

Thus, in operation, before the appearance of a voltage spike on the output node, the secondary capacitor Cs is charged and the voltage across its nodes is equal to the voltage Vdd.

The potential of the common node N is therefore zero, and the gate of the first secondary transistor Ts1 is not biased.

In the presence of a current spike on the output node, the gate Gs2 of the second secondary transistor biases and the second secondary transistor Ts2 becomes conductive.

The gate of the first secondary transistor Ts1 is therefore biased at the voltage Vdd by means of the second secondary transistor Ts2, and the first secondary transistor Ts1 therefore becomes conductive, thus short-circuiting the secondary capacitor Cs.

The potential of the common node N, and therefore the gate Gs1 of the first secondary transistor Ts1, is biased at the supply voltage Vdd, and the first secondary transistor Ts1 becomes conductive, thus short-circuiting the main capacitor.

Once the current spike on the output node has passed, the second secondary transistor Ts2 open circuits again, the voltage across the nodes of the secondary capacitor Cs increases progressively, and the potential of the common node therefore decreases progressively until reaching a zero value when the secondary capacitor is completely charged.

When the potential of the common node reaches a value lower than the triggering threshold of the first secondary transistor, the first secondary transistor close circuits again.

The inhibition of the integrator circuit by the refractory circuit thus takes place for an inhibition duration that depends on the charging speed of the secondary capacitor Cs through the secondary resistor Rs.

The inhibition duration therefore depends on the time constant of the resistive-capacitive circuit including the secondary resistor Rs and the secondary capacitor Cs.

The structure of such a refractory circuit is advantageous with respect to the refractory circuits of the prior art in that it has a reduced number of components, and as a result makes it possible to obtain a refractory circuit of which the surface area is less than two square micrometers.

According to one embodiment illustrated in FIG. 6, it would be possible to have an integrated circuit CI including a network of artificial neurons, including a plurality of neuron devices according to one or more of the embodiments described previously in connection with FIGS. 1 to 5, coupled to one another by means of their input or output node. 

1. An integrated artificial neuron device, comprising: an integrator circuit coupled between an input node at which at least one input signal is received and an output node at which the integrator circuit delivers at least one output signal; and a refractory circuit configured to inhibit the integrator circuit for an inhibition duration after the delivery of the at least one output signal, the refractory circuit comprising: a first transistor having a first conduction terminal coupled to a supply node, a second conduction terminal coupled to a common node, and a control terminal coupled to the output node; a second transistor having a first conduction terminal coupled to the input node, a second conduction terminal coupled to a reference node at which a reference voltage is received, and a control terminal coupled to the common node; and a resistive-capacitive circuit coupled between the supply node and the reference node and having a tap coupled to the common node, wherein the inhibition duration is dependent upon a time constant of the resistive-capacitive circuit.
 2. The integrated artificial neuron device of claim 1, wherein the resistive-capacitive circuit comprises a capacitor coupled between the supply node and the common node, and a resistor coupled between the common node and the reference node.
 3. The integrated artificial neuron device of claim 2, wherein the resistive-capacitive circuit comprises a capacitor directly electrically connected between the supply node and the common node, and a resistor directly electrically connected between the common node and the reference node.
 4. The integrated artificial neuron device of claim 2, wherein the capacitor comprises a MOS transistor configured for use as a capacitor.
 5. The integrated artificial neuron device of claim 4, wherein the MOS transistor of the capacitor has a surface area of one square micrometer.
 6. The integrated artificial neuron device of claim 2, wherein the resistor comprises a MOS transistor configured for use as a resistor.
 7. The integrated artificial neuron device of claim 2, wherein the resistor has a resistance of one giga-ohm.
 8. The integrated artificial neuron device of claim 1, wherein the first transistor comprises a first n-channel MOS transistor having a drain coupled to the supply node, a source coupled to the common node, and a gate coupled to the output node; and wherein the second transistor comprises a second n-channel MOS transistor having a drain coupled to the input node, a source coupled to the reference node, and a gate coupled to the common node.
 9. The integrated artificial neuron device of claim 1, wherein the first transistor comprises a first n-channel MOS transistor having a drain directly electrically connected to the supply node, a source directly electrically connected to the common node, and a gate directly electrically connected to the output node; and wherein the second transistor comprises a second n-channel MOS transistor having a drain directly electrically connected to the input node, a source directly electrically connected to the reference node, and a gate directly electrically connected to the common node.
 10. A refractory circuit configured to inhibit operation of an integrator circuit after delivery of an output signal, the refractory circuit comprising: a first transistor having a first conduction terminal coupled to a supply node, a second conduction terminal coupled to a common node, and a control terminal coupled to an output node at which the output signal is delivered; a second transistor having a first conduction terminal coupled to an input node, a second conduction terminal coupled to a reference node at which a reference voltage is received, and a control terminal coupled to the common node; and a resistive-capacitive circuit coupled between the supply node and the reference node and having a tap coupled to the common node, wherein a duration of inhabitation of the integrated circuit by the refractory circuit is dependent upon a time constant of the resistive-capacitive circuit.
 11. The refractory circuit of claim 10, wherein the resistive-capacitive circuit comprises a capacitor coupled between the supply node and the common node, and a resistor coupled between the common node and the reference node.
 12. The refractory circuit of claim 11, wherein the resistive-capacitive circuit comprises a capacitor directly electrically connected between the supply node and the common node, and a resistor directly electrically connected between the common node and the reference node.
 13. The refractory circuit of claim 11, wherein the capacitor comprises a MOS transistor configured for use as a capacitor.
 14. The refractory circuit of claim 13, wherein the MOS transistor of the capacitor has a surface area of one square micrometer.
 15. The refractory circuit of claim 11, wherein the resistor comprises a MOS transistor configured for use as a resistor.
 16. The refractory circuit of claim 15, wherein the resistor has a resistance of one giga-ohm.
 17. The refractory circuit of claim 10, wherein the first transistor comprises a first n-channel MOS transistor having a drain coupled to the supply node, a source coupled to the common node, and a gate coupled to the output node; and wherein the second transistor comprises a second n-channel MOS transistor having a drain coupled to the input node, a source coupled to the reference node, and a gate coupled to the common node.
 18. The refractory circuit of claim 10, wherein the first transistor comprises a first n-channel MOS transistor having a drain directly electrically connected to the supply node, a source directly electrically connected to the common node, and a gate directly electrically connected to the output node; and wherein the second transistor comprises a second n-channel MOS transistor having a drain directly electrically connected to the input node, a source directly electrically connected to the reference node, and a gate directly electrically connected to the common node. 